Each cylinder is provided with a first intake valve and a second intake valve, and a first intake cam for driving the first intake valve and a second intake cam for driving the second intake valve are coaxially pivotally supported on an intake camshaft. A first cam phase change mechanism which varies respective phases of the first and second intake cams relative to a crankshaft of the internal combustion engine is combined with a second cam phase change mechanism which varies a phase of the second intake cam relative to the first intake cam. The second cam phase change mechanism is set to have a variable-phase angular range wider than that of the first cam phase change mechanism.
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1. An internal combustion engine with a variable valve gear, wherein each cylinder is provided with a first intake valve and a second intake valve, and a first intake cam for driving the first intake valve and a second intake cam for driving the second intake valve are coaxially pivotally supported on an intake camshaft, and the intake camshaft is configured so that a first intake camshaft to which the first intake cam is fixed and a second intake camshaft to which the second intake cam is fixed are located coaxially, the internal combustion engine comprising:
a first cam phase change mechanism which varies respective phases of the first and second intake cams relative to a crankshaft of the internal combustion engine; and
a second cam phase change mechanism which varies a phase of the second intake cam relative to the first intake cam,
the second cam phase change mechanism being set to have a variable-phase angular range wider than that of the first cam phase change mechanism,
the second cam phase change mechanism varying a phase of the second intake camshaft relative to the first intake camshaft, and
the first cam phase change mechanism varying the phase of the second cam phase change mechanism relative to the crankshaft.
2. The internal combustion engine with a variable valve gear according to
3. The internal combustion engine with a variable valve gear according to
4. The internal combustion engine with a variable valve gear according to
5. The internal combustion engine with a variable valve gear according to
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1. Field of the Invention
The present invention relates to an internal combustion engine with a cam phase change mechanism capable of changing the phase of an intake cam.
2. Description of the Related Art
Conventionally, there are internal combustion engines that comprise a cam phase change mechanism as a variable valve gear, which changes the phase of an intake cam to vary the opening and closing timings of an intake valve. Further, a technique has been developed in which the cam phase change mechanism is applied to internal combustion engines that are provided with a plurality of intake valves for each cylinder. According to this technique, the opening and closing timings of only some of the intake valves are varied in accordance with the engine load and speed.
In one such internal combustion engine, the opening and closing timings of the specific intake valves are delayed by the cam phase change mechanism, based on the operating state of the engine, whereby the open periods of the specific intake valves, along with those of ones not subject to delay control, can be extended (Jpn. Pat. Appln. KOKAI Publication No. 3-202602).
In the internal combustion engine described in the above patent document, vane-type cam phase change mechanisms formed of vane-type actuators have become widely used to make valve trains compact. Due to structural restrictions, however, these vane-type cam phase change mechanisms cannot easily produce great phase differences. Accordingly, the opening and closing timings of the intake valves cannot be substantially changed, so that it is difficult to considerably mitigate pumping loss by greatly extending the valve-open period.
The object of the present invention is to provide an internal combustion engine with a variable valve gear, capable of delaying the closing timings of intake valves without failing to make a valve train compact and of extending the valve-open period, thereby greatly mitigating pumping loss.
In order to achieve the above object, the present invention provides an internal combustion engine with a variable valve gear, wherein each cylinder is provided with a first intake valve and a second intake valve, and a cam for driving the first intake valve and a cam for driving the second intake valve are coaxially pivotally supported on an intake camshaft, the internal combustion engine comprising a first cam phase change mechanism which varies respective phases of the cams for driving the first and second intake valves relative to a crankshaft of the internal combustion engine, and a second cam phase change mechanism which varies a phase of the cam for driving the second intake valve relative to the cam for driving the first intake valve, the second cam phase change mechanism being set to have a variable-phase angular range wider than that of the first cam phase change mechanism.
Thus, the valve-open period can be extended by making the variable-phase angular range of the second cam phase change mechanism, that is, phase differences between the respective opening and closing timings of the first and second intake valves, wider than that of the first cam phase change mechanism. By performing the delay angle control and valve-open period increasing control in, for example, low-load, low-speed operation, therefore, pumping loss can be considerably mitigated to greatly improve the fuel efficiency. Further, in-cylinder flow can be enhanced by increasing the phase differences between the respective opening and closing timings of the first and second intake valves. Thus, combustion stability can be improved even with mitigated pumping loss and at a low actual compression ratio with a small amount of air, and the fuel efficiency can be further improved. Since mixing between air and fuel is also enhanced, moreover, emission of unburned components in exhaust gas can be reduced.
The present invention will become more fully understood from the detailed description given hereinafter and the accompanying drawings which are given by way of illustration only, and thus, are not limitative of the present invention, and wherein:
One embodiment of the present invention will now be described with reference to the accompanying drawings.
As shown in
As shown in
Each cylinder of the engine 1 is provided with two intake valves (first and second intake valves 12 and 13) and two exhaust valves 16 and 17. The first and second intake valves 12 and 13 are arranged longitudinally on the right of the central part of a combustion chamber 18. The two exhaust valves 16 and 17 are arranged longitudinally on the left of the central part of the chamber 18. The first and second intake valves 12 and 13 are driven by the first and second intake cams 10 and 11, respectively. As the first and second intake valves 12 and 13 are arranged in place, the first and second intake cams 10 and 11 are alternately arranged on the intake camshaft 2.
A vane-type cam phase change mechanism formed of a conventional vane-type hydraulic actuator is used as the first cam phase change mechanism 20. The first cam phase change mechanism 20 is configured so that a vane rotor is pivotably disposed in a housing to which the gear 60a is fixed and the exhaust camshaft 3 is fixed to the vane rotor. The cam sprocket 5 is fixed to the exhaust camshaft 3.
As shown in
As shown in
The second cam phase change mechanism 50 is an electric motor configured so that the gear 60b and the first intake camshaft 21 are fixed to its main body portion 50a and the second intake camshaft 22 is connected to a rotating shaft 50b. Thus, the second cam phase change mechanism 50 can continuously adjust the phase of the second intake camshaft 22 relative to the first intake camshaft 21, that is, the opening and closing timings of the second intake valve 13 relative to those of the first intake valve 12, toward the delay-angle side. If the opening and closing timings of the second intake valve 13 are delayed relative to those of the first intake valve 12, a period between the opening timing of the first intake valve 12 and the closing timing of the second intake valve 13, that is, an intake valve-open period, is extended. In contrast with this, the intake valve-open period is reduced if the phases are equalized by advancing the opening and closing timings of the second intake valve 13 relative to those of the first intake valve 12.
An ECU 40 is provided with an input-output device (not shown), storage devices such as ROM and RAM, central processing unit (CPU), etc., and generally controls the engine 1.
Various sensors, such as a crank angle sensor 41 and a throttle sensor 42, are connected to the input side of the ECU 40. The crank angle sensor 41 detects the crank angle of the engine 1. The throttle sensor 42 detects the opening of a throttle valve (not shown). Besides the OCV 34, moreover, the second cam phase change mechanism 50, a fuel injection valve 43, a spark plug 44, etc. are connected to the output side of the ECU 40. The ECU 40 determines the ignition timing, injection quantity, etc., based on detected information from the sensors, and drivingly controls the spark plug 44 and the fuel injection valve 43. Based on the detected information from the sensors, moreover, the ECU 40 drivingly controls the OCV 34, that is, controls the operations of first cam phase change mechanisms 20. The ECU 40 drivingly controls the second cam phase change mechanisms 50.
The ECU 40 operatively controls the first cam phase change mechanism 20 in accordance with a speed N and a load L of the engine. Specifically, as shown in
The ECU 40 operatively controls the second cam phase change mechanism 50 in accordance with the engine speed N and load L. Specifically, in the low-load, low-speed operation, as shown in
In the low-load, low-speed operation of the engine 1 of the present embodiment, as shown in
In the high-load, high-speed operation, on the other hand, the second intake valve 13 is brought to the intermediate phase by the first cam phase change mechanism 20, and the valve-open period is reduced by the second cam phase change mechanism 50. Therefore, the closing timing of the second intake valve 13 is advanced relative to the case of the low-load, low-speed operation. If the second intake valve 13 is closed in, for example, the first half of the compression stroke, that is, near a region where intake air is pushed back into an intake port by a piston, the charging efficiency of the intake air can be enhanced to secure the output.
In the high-load, low-speed operation, moreover, the opening timing of the first intake valve 12 is advanced by the first cam phase change mechanism 20. Thus, by advancing the opening timing of the first intake valve 12 to or just ahead of the top dead center (TDC), for example, pumping loss in an initial stage of an intake stroke can be mitigated, and a strong inertial or pulsating supercharging effect can be obtained. In the high-load, low-speed operation, e.g., in a start mode, therefore, the starting performance can be improved by securing good combustibility along with improved fuel efficiency.
In the present embodiment, the first and second cam phase change mechanisms 20 and 50 are located on the front end portions of the exhaust and intake camshafts 3 and 2, respectively. Thus, the cam phase change mechanisms 20 and 50 can be easily installed, and the engine 1 can be compactified without substantially increasing its transverse dimension. Moreover, the first cam phase change mechanism 20 is expected to drive the first and second intake valves 12 and 13 and the second cam phase change mechanism 50. Even if the mechanism 20 is enlarged to increase its ability for this purpose, however, the longitudinal dimension and the like of the engine can be prevented from increasing.
Further, the vane-type cam phase change mechanism and electric motor are used as the mechanisms for changing the opening and closing timings of the intake valves 12 and 13. Therefore, friction can be reduced when compared with the case of a mechanism that changes the closing timing of an intake valve by increasing or reducing the valve lift, and the operation reliability and durability of the valve train can be improved.
In the present embodiment, furthermore, the second cam phase change mechanism 50 is an electric motor, so that highly responsive drive can be achieved even at low temperature. Thus, the phases of the intake cams can be quickly controlled even in, for example, a cold start mode. Further, the fuel efficiency can be improved relative to that of the hydraulic actuator. Like the first cam phase change mechanism 20, moreover, the second cam phase change mechanism 50 may be of a hydraulic drive type.
In the low-load, low-speed operation, moreover, the ECU 40 controls the second cam phase change mechanism 50 to extend the valve-open period after controlling the first cam phase change mechanism 20 for the most delayed angle. Thus, the cam phase change mechanisms 20 and 50 are not simultaneously activated but sequentially controlled, so that accurate operation control can be achieved without involving a deficiency of oil pressure even in the case where both the cam phase change mechanisms 20 and 50 are of the hydraulic drive type.
In the present invention, the map used in the operation setting for the first cam phase change mechanism 20 is not limited to the one shown in
A spring should preferably be provided for urging the second cam phase change mechanism 50 in the direction to reduce the phase difference between the first and second intake camshafts 21 and 22. By doing this, variation of the phase difference between the first and second intake valves 12 and 13 can be suppressed, so that the valve-open period can be stably controlled.
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